Differential Pressure Transmitter With Intrinsic Verification

ABSTRACT

A differential pressure transmitter is disclosed, which comprises a body for housing a high-pressure sensor and a low-pressure sensor, a plurality of high-pressure process connectors formed in said body and fluidly coupled to said high-pressure sensor for transmitting a first pressure of a process fluid to said high-pressure sensor, each of said high-pressure process connectors comprising a conduit having an opening for receiving the process fluid, a plurality of low-pressure process connectors formed in said body and fluidly coupled to said low-pressure sensor for transmitting a second pressure of a process fluid to said low-pressure sensor, each of said low-pressure process connectors comprising a conduit having an opening for receiving the process fluid, wherein said second pressure is equal to or less than said first pressure, wherein said openings of the high-pressure connectors are spaced relative to said openings of the low-pressure connectors to allow a plurality of pair-wise connections to the process fluid.

CROSS-REFERENCE TO RELATED APPLICATIONS

This present application is a continuation application of U.S. patent application Ser. No. 14/957,191, filed Dec. 2, 2015, which is a continuation-in-part of U.S. patent application Ser. No. 13/883,043, filed on Dec. 10, 2013, now U.S. Pat. No. 9,207,140, issued Dec. 8, 2015, which is a U.S. National 371 application of PCT/US2011/059114, filed Nov. 3, 2011, which claims priority to U.S. Provisional Patent Application No. 61/409,631, filed Nov. 3, 2010. Each of the above applications to which the present application claims priority is herein incorporated by reference in its entirety.

FIELD OF THE INVENTION

The invention relates to improved differential pressure transmitters with improved accuracy, their methods of use and manufacture preferably for industrial uses.

BACKGROUND OF THE INVENTION

Differential pressure transmitters require a great deal of care and maintenance in order to function properly for their intended purposes. It is common practice for differential pressure transmitters to be removed from the application or field installation and transported to well-equipped calibration laboratories to assure the accuracy of their measurement. This practice is costly and disruptive. Furthermore, calibration laboratories rarely simultaneously duplicate the combined actual process conditions of a specific transmitter. For example, an inadvertent over-range when re-installing the transmitter on-line will unknowingly compromise “assurance” of accuracy provided by the calibration. Often, a compromised partial calibration is conducted whereupon the output of the transmitter is adjusted for a zero value by a technician at the transmitter.

Unfortunately, measurement accuracy is influenced by the combination of many environmental process and environmental conditions such as process pressure, process temperature, environmental temperature, solar radiation, local neighboring thermal radiation, inadvertent over-range, electronic/mechanical drift and enclosure distortion. Although these influences are interdependent, they are usually considered as being independent. Unfortunately, the user or field technician is not routinely provided with standard techniques or methods to properly compensate for these interdependences and usually does not have the required facilities.

The present practice is to compensate for these influences without considering their interdependencies. This is pragmatically achieved by erroneously applying independent corrections for the prominent influences. This neglect of the interdependency of the various influences increases errors in measurement. Accurate compensation must be conducted taking into account the actual combined environmental and process conditions.

Conventional differential pressure transmitters having a single sensor exacerbate these detrimental influences. For example, existing single sensor, dual fill fluid volume differential pressure transmitters which tend to have differences in the fill fluid volumes, the spring rates and effective areas of pressure sensitive elements of the high and low sides will produce a detrimental differential pressure due to process pressure, process temperature or enclosure distortion acting upon these differences. Similarly, within single sensor, single fill fluid volume differential pressure transmitters having a significant difference in the spring rate of pressure sensitive elements of the high and low sides will produce a detrimental differential pressure due to process pressure, transmitter temperature or enclosure distortion acting upon these differences.

These conditions impact asset management and product quality. A user, until now, has had no recourse other than to accept the poor conditions.

SUMMARY OF THE INVENTION

The many environmental and process influences referred to earlier, are exacerbated by the current differential pressure transmitters employing a single differential pressure sensor. A single sensor differential pressure transmitter cannot compensate for process or environmental influences without determining the pressure and temperature prior to applying the compensation factors. What is proposed therefore is a novel differential pressure transmitter, wherein any compensation for environmental influences does not require monitoring of the pressure and temperature

Specifically, the object of the present invention is to provide a dual sensor differential pressure transmitter with a single fill fluid volume that intrinsically eliminates process and environmental performance influences, increases signal level while substantially reducing product costs.

In a first embodiment, the differential pressure transmitter of the invention can provide improved performance at a low product cost. In a second embodiment, the differential pressure transmitter of the invention provides enhancements satisfying more demanding applications. In a third embodiment, the differential pressure transmitter of the invention provides capabilities presently unavailable in the industry and satisfies the most demanding applications. All embodiments comprise a novel system and method for differential pressure-sensing and calibration described herein.

The proposed differential pressure transmitter intrinsically eliminates detrimental process and environmental influences and provides a remotely activated assurance of the elimination of these environmental influences traceable to NIST within +/−0.005% of the reading

With the proposed dual sensor, single fill fluid volume differential pressure transmitter, compensation does not require monitoring of the pressure and temperature. The object of the present invention is to provide a dual sensor with a single fill fluid volume differential pressure transmitter that intrinsically eliminates process and environmental performance influences, increases signal level while substantially reducing product costs.

In a first embodiment, the differential pressure transmitter comprises a body, and first and second cavities within said body connecting to a first and a second port, respectively on the exterior of said body. The transmitter further comprises first and second flexible elements assemblies within and sealed to said first and second cavities thereby forming a third and a fourth cavity and a fifth cavity connecting said third and said fourth cavities. The transmitter further comprises a fill fluid having a fluid fill volume within and connecting said third, said fourth and said fifth cavities and means of sensing the first and second position of a first and a second flexible element end within said third and said fourth cavities. The transmitter further comprises means of providing a conditioned response from the said first and said second position of a first and a second flexible element end, wherein, the said conditioned response of said first and said second flexible element end position is proportional to the desired measurement of the said differential pressure applied to said differential pressure transmitter.

In a second further embodiment the differential pressure transmitter of the invention, said aforementioned means of sensing the position of said first and said second flexible element end is achieved by sensing the capacitance between the said first and said second flexible element end and a first and second electrode. In one aspect said first and said second electrode is located within and is electrically insulated and attached to said third and said fourth cavity. In one aspect a first and a second electrical conductor is electrically attached to said first and said second electrode and said first and said second electrical conductor is sealed to contain said fill fluid within said third and said fourth cavities and electrically insulated from said body. An electronic module external to said body and electrically connected to said first and said second conductor and said body can also be provided. The electronic module senses the capacitance between said first and said second flexible element end and said first and said second electrode and provides a conditioned response indicative of the said differential pressure. The change in position of said first and said second flexible element end produces a said first and said second change in capacitance between said first and said second flexible element end and said first and said second electrode and said first and said second change in capacitance is conditioned to provide a response that is proportional to the desired measurement of said differential pressure.

In a third, further embodiment, a change in said fill fluid volume due to temperature variation, process pressure or enclosure distortion volume variation produces equal and opposing influences upon said first and said second flexible element assemblies, and said first and said second flexible element assemblies are produced or compensated to have equal ratios of spring rate to effective areas, thereby causing said temperature variation and said process pressure variation and said enclosure distortion to have minimal influence upon differential pressure measurement

As mentioned above, the invention further contemplates an electronic module. In one embodiment, the electronic module comprises means for sensing said first capacitance between said first flexible element end and said first electrode and a said second capacitance between said second flexible element end and said second electrode; means for determining the first and second position of said first and said second flexible element end by sensing said first and said second capacitance; means for determining a reference zero condition position of said first and said second flexible element end while at reference temperature and reference common pressure and no applied said differential pressure; means for determining operating zero condition position of said first and said second flexible element end while at operating temperature and operating common pressure and no applied said differential pressure; means for determining reference differential pressure condition position of said first and said second flexible element end while at reference temperature and reference common pressure and said differential pressure; means for determining operating differential pressure condition position of said first and said second flexible element end while at operating temperature, operating pressure and said differential pressure; a means for determining a first and a second difference in operating position between said operating differential pressure condition position and said operating zero condition position of said first and said second flexible element end; a means for providing an output proportional to said first and a second difference in operating position between said operating differential pressure condition position and said operating zero condition position of said first and said second flexible element end; a means for determining a first and a second difference in reference position between said reference differential pressure condition position and said reference zero condition position of said first and said second flexible element end; and a means for providing an output proportional to the said first and a second difference in reference position between said reference differential pressure position and said reference zero position of said first and said second flexible element end.

In another embodiment, the electronic module of the invention comprises means for determining said fill fluid temperature; means for determining said fill fluid pressure; means for calculating the change in said operating differential pressure condition from reference zero condition due to a change in said fill fluid temperature; means for calculating the change in said operating differential pressure condition from said reference zero condition due to a change in said fill fluid pressure; means for providing an output of said temperature; means for providing an output of said pressure; and means for providing an output of said reference zero condition thereby determining a reference zero condition.

The differential pressure transmitter of the invention may optionally further comprise a three-position valve. In one embodiment the three position valve comprises: a valve body having a first external port and a second external port to external pressures and said body having two internal transmitter ports a first internal port and a second internal port connecting to said differential pressure transmitter; a rotary valve plug having two internal flow conduits; and means of positioning said rotary valve plug to any of three-positions. In one aspect, the three positions of the valve are as follows: a first position wherein the first external port is connected to the first internal port and the second external port is connected to the second internal port; a second position wherein the first internal port is connected to the second internal port and no connection made between the first and second external ports; and a third position wherein the first external port is connected to the second internal port and the second external port is connected to the first internal port. In this aspect, normal operation of said differential pressure transmitter is configured per said first position, process isolation and said differential pressure transmitter equalization is configured per said second position and reverse operation of said differential pressure transmitter is configured per said third and wherein prior to entering said first or third positions said three-position valve enters said second position.

In another aspect, the aforementioned three position valve may further comprise means of determining said reference zero position by isolation of said differential pressure transmitter from said process while maintaining process pressure upon said differential pressure transmitter and equalization of the said differential pressure upon said differential pressure transmitter in said second position said three position valve and whereby, without any said differential pressure or with constant said differential pressure, the said differential pressure transmitter output in said normal operation is compared to the said differential pressure transmitter output in said reverse operation and provides an indication of the differences in density and/or liquid height of process fluid in the impulse lines connected to said differential pressure transmitter and thereby provides a means for the compensation of impulse line density and level influences.

In one aspect the abovementioned electronic module implements a method for compensating the combined influence of said temperature and said pressure due to said change in said fill fluid fill volume, said spring rates and said effective areas of said first and said second flexible element assemblies. In one embodiment the method comprises isolating said differential pressure transmitter from said process while maintaining said process pressure and said temperature within said differential pressure transmitter and allowing equalization of said high side and said low side; sensing said process pressure with a process pressure sensor; sensing said temperature with a process temperature sensor; sensing said operating zero condition of said first and said second flexible element at said process pressure and said temperature; calculating the deflection of said first and second flexible element due to said process pressure; calculating the deflection of said first and second flexible elements due to said process temperature; calculating the ratio of said spring rate to said effective area of said first and second flexible elements; calculating the said spring rates of said first and second flexible elements; calculating the said areas of said first and second said flexible elements; and generating and applying compensation factors for said first and said second flexible elements for said process pressure and said temperature. The aforementioned method compensating for the said differential pressure transmitter for influences of the combined influence of said temperature and said pressure due to said change in said fill fluid fill volume, said effective areas and said spring rates of said first and said second flexible element assemblies.

In another embodiment the differential pressure transmitter of the invention may optionally comprising a three position actuator. In one embodiment the three-position actuator comprises a first cylinder having a first piston and a first pressure port, the first cylinder having a stop for limiting axial motion of said first piston; and a second cylinder having a second piston, said second cylinder having an axial slot and said second piston having a radial extension positioned within said axial slot of said second cylinder; and a third cylinder having a third piston and a second pressure port, the third cylinder further comprising a stop for limiting axial motion of said third piston. A first actuator position is obtained by pressure being applied to said first cylinder through said first port, a second actuator position is obtained by pressure being applied to said third cylinder through said second port and a third position is obtained by pressure applied to said first cylinder through said first port and to third cylinder though said second port. Positioning of said center piston moves said three-position valve to said position one, said position two or said position three and said radial extension of said second piston provides a means of moving an external device to any of the said three positions.

In another embodiment, the transmitter may optionally include a gravitational pressure reference source. In one aspect, the gravitational pressure reference source comprises: a body; an internal cavity having a post; a sphere having a hole containing termination of said post that is attached to said sphere is sealed to said post; a cylinder having enlarged internal diameters at each end; a stepped cylindrical post attached to said cylinder; a cylindrical weight with an internal diameter accepting said stepped cylindrical post; and a means of securing said stepped cylindrical post to said cylindrical weight, wherein said cylinder, said stepped cylindrical post and said cylindrical weight comprise a gravitational reference assembly. The gravitational pressure reference source further comprises an internal cylindrical magnet within a cavity in said body and vertically below and concentric with said gravitational reference assembly wherein the said internal cylindrical magnet can be raised by an external magnet field with opposing magnetic poling and said raising of said internal magnet raises said gravitational reference assembly relative to said sphere and wherein upon a change of said external magnet field the said internal cylindrical magnet falls rapidly due to gravity and the said change in said external magnet field and wherein the gravitational reference assembly falls under the action of gravity producing a reference pressure in the said cavity of the said cylinder and wherein said reference pressure is applied to the internal cavity of the post. The gravitational pressure reference source may also include a means of measuring temperature by capturing the time of the descent for a known distance of the said gravitational reference assembly and a means for converting the said time of a descent for a said known distance to an average velocity of the said fill fluid through said gravitational reference assembly and from said average velocity through said gravitational reference assembly determine a viscosity of said fill fluid and from said viscosity determine said temperature from known viscosity versus temperature relationships. The response of the differential pressure transmitter upon the application of the gravity pressure reference provides a means of sensing said reference pressure for verifying calibration and determining said temperature of said fill fluid.

The differential pressure transmitter may also further comprise an actuator for actuating said gravitational pressure reference. In one embodiment the gravitational pressure reference actuator comprises: (a) a piston having a longitudinal axis, said piston having four cavities with an axis of symmetry perpendicular to and intersecting said longitudinal axis of said piston and said axis of symmetry of said four cavities and said longitudinal axis are parallel and said piston having four magnets contained within the said cavities and the magnetic poling of each said magnet alternates along said piston longitudinal axis; and (b) a cylinder with a first and a second closed end wherein said piston and said magnets are contained within said cylinder and said piston and said cylinder having means for preventing rotation of said piston within said cylinder. The cylinder has a first and a second pneumatic port located at a first and second closed end of said cylinder respectively. By applying pneumatic pressure to the first pneumatic port the piston is moved to the second closed end. Likewise by applying pneumatic pressure to the second pneumatic port the piston is moved to the first closed end of the cylinder.

In one aspect, the magnets of the aforementioned gravitational pressure reference actuator within said process enclosure are raised by external magnets by providing an axial opposing magnetic field. Likewise, said magnets within a said process enclosure are lowered by said external magnets by providing an axial additive magnetic field and wherein means is provided for actuating said gravitational pressure reference.

In one embodiment the flexible element assemblies of the differential pressure transmitter of the invention may comprise one or more axial thin cylindrical sections having, at each said axial end, a thin radial extension and wherein said thin radial extensions of successive said axial thin cylindrical sections are joined at the outermost radial position and wherein one of said axial thin cylindrical sections having said thin radial sections at said axial end is joined to a support member and opposing said axial thin cylindrical section of the said one or more axial thin cylindrical sections having said thin radial section at axial end is joined to an end member and said radial sections are normally distended in the said axial direction. Upon application of a high value of said external process pressure the said thin radial sections deflect axially until restrained by said support member and by mating of said radial sections and said flexible element ends are capable of returning to original condition after enduring said external process pressure due to the low stress encountered

In one aspect of the invention the transmitter of the invention calculates a correction factor as follows. An external, equal and common pressure is applied to the said first and second flexible element assemblies. The deflection of each of said flexible element assemblies as a result of the said compression of said fill fluid due to said pressure is sensed. The difference in the ratio of spring rate to effective area of a said first and second flexible element assemblies is determined by comparing the said displacements of the said pair of flexible element ends in response to the said common pressure. A correction factor consisting of the ratio of spring rate to effective areas of said first and second flexible element assemblies is produced and is used to compensate for said deflections of said first and second flexible element assemblies in the sensing of said differential pressures.

In addition to process and environmental influences, over-range of the differential pressure transmitter is a major influence and usually not specified or considered. If specified, it usually does not apply to worst-case conditions resulting from a combination of maximum working pressure while at maximum process temperature. The proposed differential pressure-sensing concept minimizes these over-range concerns due to hysteresis from over stressing by an assurance that the proposed concept is not highly stressed and well supported during the over-range. Zero and span return errors from overstressing as in present practice are significantly minimized. Thus an improvement in over-range performance is inherent in the proposed differential pressure-sensing concept and resolves the worst-case condition of maximum process pressure over-range at maximum process temperature.

The proposed dual sensor, single fill fluid volume differential pressure transmitter is shown in FIG. 1 and the dual sensor concept is shown in cross-section in FIG. 2. This proposed dual sensor concept does not eliminate the undesirable change in fill fluid volume occurring with changes in pressure, temperature or enclosure distortion but it does intrinsically eliminate the undesirable error influence. Any differential pressure developed due to the change in fill fluid volume for whatever cause is applied equally and opposingly to the high and the low side flexible element assemblies with no differential pressure being sensed by the differential pressure transmitter. Ideally, if the combined response of spring rates and effective areas of the high and low side flexible element assemblies are matched, there cannot be a differential pressure developed in the proposed concept due to the detrimental influences.

Optimization of the proposed concept requires design and manufacturing considerations to assure this match of the combined response of spring rates and effective areas of the high and low side flexible element assemblies of (3 A) and (3B) of FIG. 2. Although these efforts may produce a good match, it cannot be assured to be insignificant. However, an innovative simple manufacturing procedure assures these differences in the spring rates and effective areas of the high and low side flexible element assemblies due to manufacturing tolerances are insignificant. During the manufacturing process, a high pressure is simultaneously applied to the high and low side flexible element assemblies while monitoring the deflections of the high and low side flexible element ends resulting from the compression of the fill fluid. The difference in the deflection of the flexible element ends provides a means of compensating for the difference in the effective areas and spring rates of the flexible element assemblies. The equation for compensation will be developed further in the discussion and illustrates how the compensation is implemented. Thus, the difference in the spring rates and effective areas of the flexible element assemblies due to manufacturing tolerances is minimized and ideally eliminated assuring a high level of performance. Furthermore, this process can also be applied in the field. Thus, a user can verify high performance upon receipt and during routine maintenance.

The proposed dual sensor, single fill fluid volume differential pressure transmitter is simple in construction. A single fill fluid chamber exists between the high side flexible element assembly and low side flexible element assembly. Within this single chamber, there are fixed electrodes (4 a) and (4 b) of FIG. 2 that are in close proximity to each of the flexible element ends (8A) and (8B). The sensing is achieved by simultaneously measuring the differential change in capacitance due to the deflection of the flexible element end with respect to the fixed electrode for the high and the low side. A pressure applied to the high side deflects the flexible element end of the high side inwardly towards the fixed electrode and simultaneously the fill fluid causes the low side flexible element end to deflect outwardly away from the fixed electrode due to the equal displaced volume of the flexible elements assemblies.

Operation of the differential pressure transmitter in a flow or level application is categorized by four conditions that may be defined:

1. When the transmitter is assured to be at a reference temperature, reference process pressure and no differential pressure, the output is defined as “reference zero condition”.

2. When the transmitter is assured to be at a known temperature, known process pressure and no differential the output is defined as “operating zero condition”.

3. When the transmitter is assured to be at a known temperature, known process pressure and a known differential pressure with respect to “reference zero condition” is defined as “reference differential pressure condition”.

4. When the transmitter is assured to be at a known temperature, known process pressure and at a differential pressure being measured, it is defined as “operating differential pressure condition”.

The proposed advanced and premium differential pressure transmitter concepts will satisfy the requirements of more demanding applications. The advanced and premium differential pressure transmitters are composed of the standard differential pressure transmitter with ancillary devices.

There are three ancillary devices:

The advanced and premium product has an actuator that remotely operates a three-position valve for normal, equilibrate or reverse position. The equilibrate position isolates the transmitter from the process.

The premium product also incorporates a gravitational pressure reference that verifies calibration traceable to National Institute of Standards with an actuation device that provides remote operation of the gravitational pressure reference.

The proposed premium dual sensor, single fill fluid volume differential pressure transmitter concept provides capabilities that presently are not available in the industry and will now be described.

Differential pressure transmitters have been improved in recent years. An example is provided in U.S. Pat. No. 6,321,585 Sgourakes for a Differential Pressure Generator. This improvement eliminates all detrimental combined interdependent process and environmental influences of differential pressure transmitters by remotely verifying measurement accuracy within +/−0.005% of reading traceable to National Institute of Standards while transmitter is on-line at process and environmental operating conditions for flow and liquid level applications.

The present invention integrates U.S. Pat. No. 6,321,585 Sgourakes Differential Pressure Generator within the proposed premium differential pressure transmitter and with the addition of proposed ancillary devices, provides an exceptional high-performance premium differential pressure transmitter for flow and liquid level applications with remote calibration assurance.

The premium differential pressure transmitter provides significant advancements in performance. Some of the advancements enhancing the remote calibration verification of U.S. Pat. No. 6,321,585 Sgourakes for a Differential Pressure Generator are:

1. A reference zero condition value is available with each differential pressure observation providing an ability to monitor zero conditions during normal differential pressure measurement.

2. Detrimental influences of environmental temperature, process temperature and process pressure are intrinsically eliminated from the differential pressure transmitter.

3. Automatically scheduled sensor calibrations can be achieved remotely during routine sustained operation.

4. Reverse flow capability. The three-position valve provides an ability to measure normal or reverse flows.

5. Elimination of density or level differences in impulse lines is assured. This is achieved by comparing the zero condition in normal and reverse positions of the three-position valve. Any difference can be attributed to density or level differences in the impulse lines and the influence compensated.

6. The transmitter provides greater range limits by providing lower span capability avoiding the cost and complexity of multiple transmitters with intermediate spans.

7. Minimal over-range influence.

8. A very low cost of manufacture.

9. Calibration is assured to be within +/−0.005% of reading traceable to National Standards Institute, achieved from remote locations without a technician present at transmitter, at actual combined operating conditions, on-line and without flow interrupt.

10. Pro-active maintenance can respond if a trend of concern develops from sequential calibration assurances or from monitoring of the zero value at each differential pressure acquisition.

11. Instantaneous assurance of proper operation can be remotely verified within minutes during crisis conditions.

12. Eliminates the need to interrupt signal, remove transmitter from process line, hand written manual calibration history management, lengthy evaluations in a calibration laboratory requiring the simulation of process pressures and environmental temperatures.

13. Provides a capability for remotely scheduled customer/buyer audits eliminating skilled operators, costly travel, hotel accommodations and seasoned resources.

14. The present capacitive single sensor concepts are typically a stretched diaphragm with an effective area of approximately ⅓ inch squared with non-linear deflection. Conversely, the proposed capacitive concept has an effective area of 3.5 inches squared with linear deflection. Thus providing a factor often improved sensitivity.

In one aspect, a differential pressure transmitter is disclosed, which includes a body for housing a high-pressure sensor and a low-pressure sensor, and a plurality of high-pressure process connectors formed in said body and fluidly coupled to said high-pressure sensor for transmitting a first pressure of a process fluid (e.g., a liquid, gas or steam) to said high-pressure sensor. Each of the high-pressure process connectors includes a conduit having an opening for receiving the process fluid. The differential transmitter further includes a plurality of low-pressure process connectors formed in said body and fluidly coupled to said low-pressure sensor for transmitting a second pressure of a process fluid to said low-pressure sensor. Similar to the high-pressure process connectors, each of the low-pressure process connectors includes a conduit having an opening for receiving the process fluid, wherein said second pressure can be equal to or less than said first pressure. The openings of the high-pressure connectors are spaced relative to the openings of the low-pressure connectors to allow a plurality of pair-wise connections to the process fluid. In some embodiments, the process fluid is a flowing fluid and the first pressure corresponds to an upstream pressure and the second pressure corresponds to a downstream pressure.

In some embodiments, at least one pair of the high-pressure and low-pressure process connectors are separated from one another by about 2 inches, and at least one pair of the high-pressure and low-pressure process connectors are separated from one another by about 2⅛ inches, and at least one pair of the high-pressure and low-pressure process connectors are separated from one another by about 2¼ inches (or metric equivalents thereof). In some embodiments, the ability for multiple pair-wise connections of the process connectors to the process fluid can eliminate the need for adapters for connecting the transmitter to the process fluid in different configurations with differing separations.

In some embodiments, the body of the transmitter has at least two opposed lateral (side) surfaces (for example, the body can have a generally parallelepiped shape). In some such embodiments, the openings of the high-pressure process connectors and those of the low-pressure process connectors are disposed on the same side surface. Alternatively, at least one opening of the high-pressure process connectors can be disposed on one lateral surface of the transmitter's body and at least one opening of the low-pressure process connectors can be disposed on another lateral surface of the body (e.g., an opposed lateral surface).

In some embodiments, at least one of the conduits of the high-pressure process connectors is substantially parallel to at least one of the conduits of the low-pressure process connectors (e.g., they are parallel within about 5 degrees). In some embodiments, a high-side connection manifold fluidly connects all of the high-pressure process connectors to a high-pressure central conduit, which in turn guides the process fluid to the high-pressure sensor, and a low-side connection manifold fluidly connects all of the low-pressure process connectors to a low-pressure central conduit, which in turn guides the process fluid to the low-pressure sensor.

In some embodiments, the body of the transmitter includes one enclosure for receiving the high-pressure sensor and another enclosure for receiving the low-pressure sensor. The sensors can be configured to capacitively measure a pressure differential of the process fluid upon the sensors.

In some embodiments, the differential pressure transmitter can further include a first isolation valve for isolating said high-pressure sensor from the pressure of the process fluid when closed and a second isolation valve for isolating said low-pressure sensor from the pressure of the process fluid when closed. Further, in some embodiments, the differential pressure transmitter can further include a first vent valve coupled to said high-pressure sensor for exposing said sensor to an external environment different from the high-pressure sensor enclosure when opened and a second vent valve coupled to said low-pressure sensor for exposing said sensor to an external environment different from the low-pressure sensor enclosure when opened. By way of example, the external environment can be ambient atmosphere. Further, in some embodiments, the differential pressure transmitter can further include a pressure equalization valve disposed between said high-pressure sensor and said low-pressure sensor.

In some embodiments, the differential pressure transmitter includes two pressure equalization valves, where one of those valves is fluidly coupled to the high-pressure sensor and the other valve is fluidly coupled to the low-pressure sensor with the equalization valves coupled to one another via a process fluid-filled conduit. A single vent valve can be coupled to the two equalization valves, for example, for venting the system to atmosphere.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an isometric view of the differential pressure transmitter.

FIG. 2 is a cross sectional view of the proposed differential pressure sensor of the differential pressure transmitter.

FIG. 3 is an isometric view of the premium differential pressure transmitter with integrated three-position valve and valve operator and gravitational reference with operator.

FIG. 4 is a schematic view illustrating the three position hydraulic connections.

FIG. 5 is a view showing the three-position valve components in the normal position.

FIG. 6 is an isometric view of the three position valve components in the equilibrate position.

FIG. 6A is a cross sectional view of the three position valve in the equilibrate position with center piston positioned in center position.

FIG. 7 is a cross sectional view of the gravitational pressure reference with the actuator in the normal run position.

FIG. 8 is a cross sectional view of the gravitational pressure reference with the actuator having raised the weight and cylinder assembly and prepared to initiate development of the gravitational pressure reference.

FIG. 9 schematically depicts a conventional approach for connecting a differential pressure transmitter to a process fluid conduit.

FIG. 10A schematically depicts a differential pressure transmitter according to an embodiment of the present teachings, illustrating the process connectors, valves and pressure sensors.

FIG. 10B is a partial isometric view of the differential transmitter depicted in FIG. 10A, illustrating a pair of enclosures in which the high-pressure and the low-pressure sensors of the differential pressure transmitter are disposed.

FIG. 10C is a partial schematic view of the differential pressure transmitter depicted in FIG. 10A (differential pressure transmitter 900), depicting some of the internal conduits thereof.

FIG. 10D is a schematic view of the process-connectors and internal connections of the differential pressure transmitter depicted in FIG. 10A.

FIG. 11 schematically depicts a process connector of the differential pressure transmitter depicted in FIG. 10A connected to a pipe containing a process fluid.

FIG. 12 schematically depicts the internal connections of another implementation of the differential pressure transmitter depicted in FIG. 10A according to the present teachings

DETAILED DESCRIPTION OF THE INVENTION

The proposed dual sensor, single fill fluid volume differential pressure transmitter (1) is illustrated in FIG. 1 with the major components shown as a body (2), two process interface assemblies (3A) and (3B), high pressure process port (12) and low pressure process port (13).

The dual sensor, single fill fluid volume differential pressure transmitter (1) of FIG. 1. is very compact and optimized to accommodate present impulse line spacing of 2⅛″ between high-pressure process port (12) and low-pressure process port (13). The flexible element assembly (3A) of FIG. 2, is composed of a flexible element end (8A) and two convolutions (9AA) and (9AB). The flexible element assembly (3A) is attached to a base (15A) having an isolation groove (16A) that minimizes influences from distortion of the body (2) due to process pressure or process/environmental temperature. Additional components are the fill fluid (14), fill fluid connecting tube (11) and fill fluid filling ports (10A) and (10B).

The dual sensor measures the differential pressure by sensing the capacitance change due to the deflection of flexible element end (8A) with respect to the fixed electrode (4A) as shown in cross section 2-2 of FIG. 2. and simultaneously the deflection of flexible element end (8B) with respect to the fixed electrode (4B). The flexible element assemblies (3A) and (3B) thereby provide process isolation and a differential pressure sensing capability.

The flexible element assembly (3A) has an electrode (4A) mounted upon an insulator (5A) that is attached to the base (15A). The electrode (4A) has an electrical conductor (6A) providing electrical continuity from the electrode (4A) to an electrical termination (17A) of hermetic seal (7A). The electrical conductor (6A) has a stress relief (not shown) that minimizes thermal expansion and pressure expansion influences to assure reliable connectivity between electrode (4A) and the electrical termination (17A) of the hermetic seal (7A). Additionally, the electrical conductor (6A) is contained within an insulator (18A) to minimize undesirable capacitive coupling and restrict relative motion between the conductor (6A) and the body (2).

A fill fluid (14) hydraulically couples the flexible element assembly (3A) of the high side to the flexible element assembly (3B) of the low side. Thus a high pressure applied to a flexible element assembly (3A) of the high side causes an inward deflection while the opposing flexible element assembly (3B) experiences an outward deflection.

The equations predicting the differential pressure considering the position of the flexible element ends (8A) and (8B) and the ratio of spring rate to effective area of the flexible elements (9AA), (9AB), (9BA), and (9BB) of FIG. 2. are developed as follows:

Definitions

-   PHS=Pressure sensed on high side -   PI=Internal pressure of fill fluid -   P=Process pressure on high and low side -   KH=Spring rate flexible element assembly high side -   KL=Spring rate flexible element assembly low side -   AH=Effective area flexible element assembly high side -   AL=Effective area flexible element assembly low side -   DHR=Position of high side flexible element end with PHS -   DHZ=Position of high side flexible element end without differential     pressure -   DLR=Position of low side flexible element end with PHS applied to     high side -   DLZ=Position of low side flexible element end with no differential     pressure

The summation of the forces applied to flexible element ends are determined as follows:

AH * (PHS + P − PI) − KU * (DHR − DHZ) = 0 Sum  of  forces  on  high  side  flexible  element ${{PHS} + P - {PI}} = \frac{{KH}*\left( {{DHR} - {DHZ}} \right)}{AH}$

d/p of high side flexible element

AL * (PI − P) − KL * (DLR − DLZ) = 0 Sum  of  forces  on  low  side  flexible  element ${{PI} - P} = \frac{{KL}*\left( {{DLR} - {DLZ}} \right)}{AL}$

d/p of low side flexible element

${PHS} = {{\frac{KH}{AH}*\left( {{DHR} - {DHZ}} \right)} + {\frac{KL}{AL}\left( {{DLR} - {DLZ}} \right)}}$

Desired equation for differential pressure

Thus the sum of the deflections of the flexible element ends is proportional to the differential pressure.

This equation requires the actual value of each ratio of spring rate to effective areas of the flexible element assemblies be known. Alternatively, an innovative procedure has been developed. In this procedure, a high process pressure is applied to the high process pressure port (12) and simultaneously to the low process pressure port (13) thereby compressing the fill fluid volume (14). The compression of the fill fluid is sensed by the deflection of each flexible element end. The ratio of these deflections provides a means of compensating the ratios of spring rate to effective area of the two flexible element assemblies. The compensation is developed as follows:

Definitions

-   -   PI=Process pressure internal     -   P=Process pressure high and low side     -   DLP=Position of low side     -   DHP=Position of high side     -   T=Temperature difference from a reference temperature     -   a=Coefficient of thermal change in volume     -   b=Bulk Modulus Coefficient of pressure change to volume change

A force balance summation of each flexible element assembly provides the desired relation to be used in the compensation.

(P − PI) * AH − KH * DHP = 0 (P − PI) * AL − KL * DLP = 0 ${P - {PI}} = \frac{{KH}*{DHP}}{AH}$ ${P - {PI}} = \frac{{KL}*{DLP}}{AL}$ ${DHP} = \frac{DLP}{\frac{{KH}*{AL}}{{AH}*{KL}}}$

Equating pressures and solving for desired ratio

$K = \frac{{KH}*{AL}}{{AH}*{KL}}$ ${DHP} = \frac{DLP}{K}$

Abbreviate

The ratios of spring rate to effective area of the two flexible element assemblies can now be compensated using this factor. Compensation is achieved by arbitrarily selecting the high side flexible element assembly as a reference and applying the compensation factor to the low side flexible element assembly. Thus the compensated equation becomes:

${PHS} = {{\frac{KH}{AH}*\left( {{DHR} - {DHZ}} \right)} + {\frac{KL}{AL}*\frac{{DLR} - {DLZ}}{K}}}$

The compensation also requires a change in reference from KL/AL to KH/AH for the low side.

Thus, the desired differential pressure can be sensed from the deflection of the compensated flexible element assemblies without a need to determine the actual value of the spring rate or effective area of each flexible element assembly. An overall calibration coefficient would include the ratio of spring rate to effective area and an additional factor for setting the output for a given input.

It will now be shown how the compensated equation intrinsically eliminates the detrimental influences of process and environmental influences. A change in the common fill fluid volume will cause an equal and opposing change in the differential pressure applied upon each of the flexible element assemblies but will not cause any change in the total differential pressure sensing. This is an important and basic benefit, for process temperature, process pressure, environmental temperature and enclosure distortion will change the common fill fluid volume. Therefore the detrimental performance influences are intrinsically eliminated.

An equation considering the detrimental influences will illustrate the manner in which they are intrinsically eliminated. The deflection associated with the detrimental differential pressure due to an increased process pressure compressing the fill fluid volume can be determined from the following equations:

${DPH} = \frac{P*\beta*V}{2*{AH}}$ ${DPL} = {\frac{P*\beta*V}{2*{AL}}*\frac{AL}{AH}}$ DPH = DPL

Similarly, the deflection associated with the detrimental differential pressure due to due to an increased temperature expanding the fill fluid volume can be determined from the following equations:

${DTH} = \frac{T*\alpha*V}{2*{AH}}$ ${DPL} = {\frac{T*\alpha*V}{2*{AL}}*\frac{AL}{AH}}$ DTL = DTH

Including these influences within the basic equation provides:

${PHS} = {{\frac{KH}{AH}*\left( {{DHR} - {DHZ}} \right)} + {DPH} - {DTH} + {\frac{KH}{AH}*\frac{{DLR} - {DLZ}}{K}} - {DPL} + {DTL}}$

This complete, compensated equation reveals that the detrimental influences are equal and opposing and are therefore intrinsically eliminated. The need to continually sense the process pressure and process temperature and apply an instantaneous compensation is eliminated.

AH and AL can be verified with the three-position valve in the equilibrate position. With the addition of a temperature and pressure sensors, an awareness of the thermal coefficient of volumetric change and the bulk modulus of the fill fluid, the fill fluid volume and the sensed total deflection DTPH and DTPL provides a means to determine AH and AL.

DTPH = DTH = DPH  and  DTPL = DTL + DPL ${DTH} = {{\frac{T*\alpha*V}{2*{AH}}{DPH}} = {{DPH} = {{\frac{P*\beta*V}{2*{AH}}*{AH}} = {\frac{V}{2*{DTPH}}*\left( {t*\alpha*P*\beta} \right)}}}}$ ${AL} = {\frac{V}{2*{DTPH}}*\left( {{t*\alpha} + {P*\beta}} \right)}$

Ancillary Devices

The ancillary devices providing the desired enhancements of the differential pressure transmitter (1) are the three-position valve, valve actuator, gravity pressure reference and the gravity reference actuator. All ancillary devices are contained within an assembly (14) of FIG. 3. They will be described sequentially in the following description.

The three-position valve configures the proposed differential pressure transmitter (1) for normal, equilibrated or reverse operation and are shown schematically in FIG. 4. The main components of the proposed three-position valve and valve operator (20) are shown in FIG. 5 and now considered.

The normal position of FIG. 4. connects a high-pressure process port to a high-pressure differential pressure transmitter port and a low-pressure port to a high-pressure differential pressure transmitter with a normal flow direction.

Equilibrate position of FIG. 4. connects a high-pressure differential pressure transmitter port to a low-pressure differential pressure transmitter port equilibrating pressures and no differential pressure being applied to the differential pressure transmitter.

Reverse position of FIG. 4. connects a high-pressure process port to a high-pressure differential pressure transmitter port and a low-pressure process port to a low-pressure differential pressure transmitter port providing reverse flow measurement capability. Although the differential pressure transmitter (1) remains in the same position, the high-pressure and low-pressure ports of the reverse position of the differential pressure transmitter (1) are opposite the high-pressure and low-pressure ports of the normal position.

The three position valve and operator (20) as shown in FIG. 5 is composed of a fixed valve seat (21) that is restricted from rotation by a matching key way in the body (2) that is not shown and provides the ports for communication with the differential pressure transmitter (1), a selector disc (22) that is rotated to configure the desired positions of FIG. 4, a compensation plate that is not shown, provides axial compensation for thermal and pressure deflections and torsionally couples selector disc (22) to rotor (24), an axial spring (23) that provides a load to selector disc (22) and rotor (24) assuring that selector disc (22) achieves a seal with valve seat (21) while compensating for thermal and pressure deflections, rotor (24) is driven by a crank (26) of three position actuator.

The novel three-position actuator of the three-position valve (20) is shown in cross section 2-2 of FIG. 6A for the equilibrate position. The center piston (29) is driven to the equilibrate position by applying pressure to port (33) that acts upon piston (30) forcing it to the right until arrested by stop (35) in cylinder of lower molding (32) and simultaneously applying pressure to port (34) that acts upon piston (31) forcing it to the left until arrested by stop (36) in the cylinder of lower molding (32).

The normal and reverse positions of the valve actuator are achieved by motion of three pistons (30), (31) and (32) having an innovative sequence. Referring to FIG. 6A, when the pneumatic port (33) on the left is pressurized, the left piston (30) travels to the right and engages the center piston (29) and sequentially engages the right piston (31) and continues to the right until piston (30) is limited by a stop (35) at this time the pressure is applied to center piston (29) through path (38A) and piston (31) is then driven to the right termination of the cylinder. Similarly, when the pneumatic port (34) on the right is pressurized, the right piston (31) travels to the left and engages the center piston (29) and sequentially engages the left piston (30) and continues to the left until piston (31) is limited by a stop (36) at this time the pressure is applied to center piston (29) through path (38B) and piston (30) is then driven to the left termination of the cylinder.

Motion of piston (29) of FIG. 6A actuates the valve. A post (37) of the center piston (29) is attached to valve plate (28) and valve plate (28) is coupled to a crank (26). As post (37) is positioned to the left, center and the right, it rotates the crank (30) of the three-position valve (20). The crank (26) turns the rotor (24) that positions the selector disk (22) to the desired valve position. The valve may also be operated manually by positioning valve plate (28) by hand. Valve plate (28) provides an indication of the position of the valve.

The three-position valve (20) provides the ability to determine and remove the influence of level or density in impulse lines. With a constant flow or ideally no flow, the three position valve (20) is first positioned in the normal position and the normal value of the differential pressure transmitter (1) is determined. Then the three-position valve (20) is positioned in the reverse position and the reverse value of the differential pressure transmitter (1) is determined. The results are compared and a correction made to minimize any level or density differences in the impulse lines.

The gravity pressure reference (40) shown in cross section 3-3 of FIG. 7, functions is described in detail in U.S. Pat. No. 6,321,585 Sgourakes for a Differential Pressure Generator. However, the basic operation is as follows:

The weight and cylinder assemblies (43A) and (43B) are raised with respect to fixed spherical pistons (41A) and (41B) and then allowed to descend under the action of gravity thereby producing a traceable, reliable reference pressure within the cylinders (42A) and (42B) that is applied to the differential pressure transmitter (1).

The principle of operation is simple. The weight and cylinder assembly (43A) on the high side has the same volume as the weight and cylinder assembly (43B) on the low side. The desired reference differential pressure is developed by a density difference of the weight and cylinder assembly (43A) with respect to the weight and cylinder assembly (43B). The density of the fill fluid changes significantly due to volume changes with respect to pressure or temperature. However, the fill fluid changes produce equal influences upon the assemblies and therefore do not influence the desired reference differential pressure. Thus the reference differential pressure is not influenced by fill fluid density variations that occur with temperature or process pressure.

Innovative concepts have now been provided to enhance the raising and the descent of the weight and cylinder assemblies (43A) and (43B) of FIG. 7. Located within the enclosure are internal magnets (45A) and (45B) that are raised by an opposing magnet field or lowered by an attractive magnetic field. These magnet fields are produced externally.

Positioning an external magnet (48) having an opposing magnetic orientation to the internal magnet (45) produces an opposing magnetic field that raises the internal magnet. Positioning an external magnet (48) having an attractive magnetic orientation to the internal magnet (45) produces an attractive magnetic field that lowers the internal magnet.

The positioning of the external magnets with respect to the internal magnets is simply done by shuttling the external magnets horizontally left or right a distance equal to the one half the horizontal distance between the internal magnets (45A) and (45B). This motion is illustrated in FIG. 7 illustrating the relationship in normal operation desiring to capture the internal magnets by providing an attractive field and reduce vibration of the internal magnets. Fewer magnets could be used but the desired advantage of capturing the internal magnets in normal operation thereby reducing pressure pulsations would not be achieved.

In the moment prior to the descent of the weight and cylinder assemblies (43A) and (43B) the internal magnets are held in a position illustrated in FIG. 8. To initiate a descent the external magnets (48) are quickly returned to the normal position. At this time the weight assemblies (43A) and (43B) experience a gravitational force that is applied upon the effective area defined by the sphere within the cylinder thereby producing the desired differential pressure.

The positioning of the external magnets is achieved by pneumatic pressure applied to either end of the piston (47) carrying the external magnets (48).

In another aspect, the present teachings provide improved connectors for connecting a differential pressure transmitter according to the present teachings to a process fluid. By way of background, conventional differential pressure transmitters are configured to provide three standardized process connector spacings of 2 inches, 2⅛ inches, and 2¼ inches (or metric equivalents thereof) using a process connection adapter having an eccentric connection port with respect to two bolt holes of the connection adapter. For the 2-inch spacing, the eccentricities are positioned toward each other, for the 2¼-inch spacing, the eccentricities are positioned away from one another, and for the 2⅛-inch spacing, the eccentricities are positioned in the same direction. By way of illustration, FIG. 9 schematically depicts a conventional approach for connecting a sensor (S) to a process fluid conduit (PFC) using an adaptor (A).

Such conventional connectors suffer from a number of shortcomings. In particular, such connectors typically require significant material for their adaptors and for mating requirements of an isolation manifold and sensor. For example, many such conventional adapters require four bolts for attachments to their isolation manifolds and/or sensors, and increased material in the differential pressure transmitter to provide eight threaded bolt holes to capture the four bolts in either of two transmitter positions. Furthermore, many such conventional connectors require two process compatible elastomeric seals for adapters but as many as six seals for complete installation of adapters, isolation manifolds and sensors. When the connector position is changed, the process compatible elastomeric seals must be replaced to assure reliable sealing. Moreover, many conventional connectors require an inventory of process compatible seals for accommodating the process fluid at temperature and pressure requirements of different process fluid environments.

For example, some conventional process connectors were introduced with a differential pressure transmitter having a sensor clamped between two covers. The covers had increased material to provide eight threaded bolt holes for fastening the adapters. The eight threaded bolt holes were required to provide four bolts for mounting process connectors on either of the two sides of the differential pressure transmitter for different installation positions.

FIGS. 10A and 10B schematically depict a differential pressure transmitter 900 according to an embodiment, which provides flexibility for connecting the transmitter to a process fluid in a plurality of different coupling configurations and solves the above-shortcomings of conventional process connectors. The differential transmitter 900 includes a body 902 that is configured to house a high-pressure sensor 904 and a low-pressure sensor 906. In particular, in this embodiment, the body 902 has a generally parallelepiped shape, with a rectangular cross-sectional profile, and includes two enclosures 908 and 910 for housing, respectively, the high-pressure sensor 904 and the low-pressure sensor 906.

In this embodiment, the high-pressure and low-pressure sensors are capacitive sensors implemented in a manner discussed above (See, e.g., FIG. 2 and the associated description).

The differential transmitter 900 includes three high-side process connectors 912, 914, and 916 that are fluidly coupled to the high pressure sensor 904, and three low-side process connectors 918, 920, and 922 that are fluidly coupled to the low pressure sensor 906. In this embodiment, each of the process connectors is in the form of a conduit having a threaded opening. As discussed in more detail below, these process connectors can be pair-wise utilized to connect the differential transmitter to a process fluid (e.g., a process liquid, gas or steam). For example, in this exemplary implementation, the process connectors 912 and 918 are employed to fluidly connect the differential transmitter to a process fluid, via tubings 917 and 919, respectively, and the other process connectors (i.e., process connectors 914, 916, 920 and 922) are sealed, e.g., by using plugs 914 a, 916 a, 920 a, and 922 a.

With continued reference to FIG. 10A as well as FIG. 10C, each of the process connectors 912, 914, 916, 918, 920, and 922 includes a fluid conduit having a threaded opening that allows coupling the process connector (e.g., via appropriate tubing or pipe) to the process fluid. For example, in this embodiment, the process connector 912 includes a conduit 912 a having a threaded opening 912 b. The threaded opening 912 b allows coupling the process connector 912 to the process fluid, and the conduit 912 a allows the process fluid to reach the high-pressure sensor 904. The other process connectors can be fluidly coupled to the process fluid in a similar fashion. More specifically, the process connectors 914, 916, 918, 920, and 922 include, respectively, fluid conduits 914 a, 916 a, 918 a, 920 a, and 922 a and threaded openings 914 b, 916 b, 918 b, 920 b, and 922 b. FIG. 11 schematically depicts pipes 917 and 919 coupled, respectively, to the high-pressure process connector 912 and the low-pressure processor connector 918 to allow fluidly coupling a process fluid to the differential pressure transmitter.

Referring to FIG. 10A, while in this embodiment, all of the process connectors 912, 914, 916, 918, 920, and 922 are disposed on a single lateral side (900 a) of the body 902, in other embodiments, one or more of the process connectors can be disposed on different lateral surfaces of the body 902.

With reference to FIG. 10C, FIG. 10D as well as FIG. 10A, in this embodiment, each of the high-pressure process connectors 912, 914, and 916 is fluidly connected via a high side connection manifold 1000 to a central conduit 1002 that couples the process fluid to the high-pressure sensor 904. Further, each of the low-pressure process connectors 918, 920, and 922 is coupled via a low side connection manifold 1004 to a central conduit 1006 that couples the process fluid to the low-pressure sensor 906. In this embodiment, the conduits of the process connectors are substantially parallel to one another (i.e., any deviation from being parallel is less than 5 degrees). In other embodiments, the conduits of the process connectors may not be parallel to one another.

In this embodiment, the openings of the process connectors 912 and 918 are separated (laterally separated) by 2 inches, and the openings of process connectors 914 and 920 are separated by 2⅛ inches and the openings of the process connectors 916 and 922 are separated by 2¼ inches. Thus, the process connectors provide three standardized process connector spacings and allow fluidly coupling the differential pressure transmitter to a process fluid using pair-wise process connectors corresponding to any of these spacings with a highly reliable metal-to-metal pipe thread seal without a need for adapters, bolts and process compatible seals.

With continued reference to FIG. 10C, in this embodiment, the differential pressure transmitter 900 further includes a vent valve 2000 for coupling the high-pressure sensor 904 to an external environment, e.g., ambient atmosphere or an external device, for example for venting the high-pressure sensor 904. The differential pressure transmitter 900 further includes an isolation valve 2002 for isolating the high-pressure sensor 904 from the pressure of the process fluid. In other words, the isolation valve 2002 can be closed to isolate the high-pressure sensor 904 from the process fluid. A valve 2006 allows isolating the low-pressure sensor from the process fluid. Another valve 2004 allows equalizing the pressure between the high-pressure sensor and the low-pressure sensor when isolation valve 2002 and isolation valve 2006 are closed.

Furthermore, a vent valve 2008 allows coupling the low-pressure sensor 906 to an external environment, e.g., ambient atmosphere or an external device, for example, to vent the low-pressure sensor. In use, prior to performing pressure measurements, the isolation valves 2002 and 2006 can be closed to isolate the high-pressure as well as the low-pressure sensors from the process fluid. The valve 2004 can then be opened to equalize the pressure between the high-pressure and the low-pressure sensors so as to calibrate the system. Subsequently, in order to return to service, the isolation valves 2002 and 2006 can be opened to expose the high-pressure and the low-pressure sensors to the process fluid followed by closing the equalizing valve 2004.

FIG. 12 schematically shows the internal connections of another embodiment of a differential pressure transmitter that includes two isolation valves 1200 and 1201 coupled, respectively, to the high-pressure sensor 904 and the low-pressure sensor 906. In some embodiments, the configuration shown in FIG. 12 can be used when the process fluid is natural gas. In this embodiment, two equalizer valves 1202 and 1203 couple the high-pressure sensor 904 and the low-pressure sensor 906 to a single vent valve 1204, which can be used to couple the high-pressure sensor, the low-pressure sensor, or both to an external environment (e.g., ambient atmosphere). 

1.-17. (canceled)
 18. A differential pressure transmitter, comprising a pair of flexible element assemblies each of which is in fluid communication with a respective pot, a connector tube containing a fill fluid for hydraulically coupling said flexible element assemblies, and means for determining a differential pressure applied to said ports. 